基于ITS序列分析对海南普通野生稻籼粳分化的研究

对海南普通野生稻的18个居群分别进行ITS序列克隆和测序,研究海南普通野生稻居群的籼粳分化。结果表明,海南普通野生稻的ITS序列居群间差异性显著,ITS1长度为163~239 bp,G+C含量变化范围为53.5%~77-2%。ITS2长度为165~243 bp,G+C含量变化范围为54.5%~74.2%。ITS1和ITS2区简约信息位点分别为108个和145个,单一信息位点分别为7个和2个。InDel(插入/缺失)位点分别为133个和145个,发现了9个ITS籼粳特异性位点。ClustalX软件排序及Mega构树结果表明,海南普通野生稻存在籼粳分化,偏籼型有10个居群,偏粳型有8个居群。本研究有助于揭示海南普通野生稻在起源演化上的地位,并为有效利用海南优良野生稻种质资源提供理论依据。     

东亚七筋姑多倍体ITS区的序列测定与分析

通过对13个东亚七筋姑二倍体居群和5个四倍体居群的ITS区(包括ITS1、5.8SrDNA和ITS2)进行克隆测序。ITS序列长度显示出比较高的多态性,ITS1长度为171~270bp,ITS2长度为205~238bp,5.8S序列的长度在162~164bp之间,序列中G C含量为45.83%~54.13%,当空位(gap)作缺失处理时,东亚七筋姑ITS区全序列排序后的长度为682bp,其中简约性位点289个;最大简约法分析获得一致性指数(CI)为0.630,保留系数(RI)为0.684,四倍体居群没有单独聚为一支,而是和相邻地理单元的二倍体居群聚为一支,本研究结果支持东亚七筋姑异地多起源的推断。     

基于ITS序列分析钩苞大丁草九个居群的亲缘关系

该研究对我国西南地区钩苞大丁草(Gerbera delavayi)9个居群rDNA ITS序列进行PCR的扩增和检测序列,并以非洲菊(G.jamesonii)的ITS序列作为外类群,比较了序列之间的差异,同时分析了钩苞大丁草不同居群在地理距离与遗传距离之间的关系,构建了NJ系统发育树。结果表明:(1)钩苞大丁草9个居群的ITS序列全长介于600~700 bp之间,平均长度约为657 bp,其中,ITS1长度为243~246 bp,(G+C)含量为45.67%~46.80%之间,5.8S长度191~193 bp,(G+C)含量为58.60%~58.61%之间,ITS2长度为220~221 bp,(G+C)含量为57.00%~57.45%之间;ITS序列共有22个变异位点,ITS1序列(17个)、5.8S序列(2个)以及ITS2序列(3个)上均有变异。(2)地理距离与遗传距离有正相关(r2=0.652),序列间遗传分化距离为0.001 1~0.024 3,其中普洱居群与其他居群间遗传距离最大。(3)钩苞大丁草9个居群分成三个分支,普洱居群单独成支,丽江和洱源居群聚为一支,富源、武定、德昌、石林、新平和开远6个居群聚为一支。rDNA ITS序列可以用于钩苞大丁草群体遗传研究的分析,该研究结果为其保护性开发提供了参考依据。     

甘肃本地产当归、黄芪和大黄的rDNA ITS序列分析

本研究采用改良CTAB法分别提取18份甘肃本地产当归、黄芪和大黄基因组DNA,并用PCR分别扩增其ITS1-5.8S-ITS2序列、直接测序并作序列同源性比对分析。双向测序分析结果表明,甘肃6个不同产地当归rDNA的ITS1、5.8S和ITS2序列一致,片段长度分别为215bp、162bp和223bp;供试的黄芪ITS1、5.8S和ITS2序列分别为228bp、164bp和210bp;大黄ITS1、5.8S和ITS2序列分别为160bp、159bp和164bp。供试材料的ITS1-5.8S-ITS2核苷酸序列已提交GenBank。本研究为提供甘肃当归、黄芪和大黄指纹图谱鉴别的分子标记、其道地性药材的分子鉴定和品质评价提供参考。     

江苏海域几种绿潮藻类rDNA ITS序列分析

于2009年5-7月定点采集了江苏海域绿潮藻类,测定、分析了这些藻类核糖体rDNA ITS序列,并进行分类鉴定。研究结果显示,ITS+5.8S序列片段长度为552-578 bp,其中ITS1序列部分长度为179-182 bp,5.8S序列全长为155-158 bp,ITS2序列全长为180-196 bp,序列的平均GC含量(contents)为61.6%-63.3%,不同ITS序列存在不同的插入/缺失位点。扩增得到27个序列中有7个不同序列,依据NCBI数据库相似性查找、系统进化关系及遗传距离等分析结果,确定有4个种类:浒苔(Ulva prolifeya),缘管浒苔(U.linza),石莼属(Ulva sp.)1种及盘苔属(Blidingia sp.)1种。分析表明,ITS序列可作为石莼科种类鉴定的标记。     

长苞铁杉nrDNA ITS区假基因化拷贝的克隆及序列分析研究

NrDNA作为一个重要的工具,在许多分类等级上被广泛地应用于系统发育的分析。以长苞铁杉(Nothotsuga longibracteata)为实验材料,通过nrDNA ITS区特异拷贝的克隆及假基因化分析,在序列水平上探讨假基因化的特征,进而探讨引起多拷贝基因家族假基因化的分子机制。实验结果表明:假基因化拷贝的序列长度为1 745 bp,比其它拷贝短11 bp-12 bp;GC含量明显偏低,特别是5.8 S区和ITS2区的GC含量分别比其它克隆低6.15%-6.17%和5.75%-6.15%;5.8 S区和ITS2区序列变异大,遗传距离(d)分别为0.0718 0.0221和0.0691 0.0178;在系统发育的分析中出现异常的长枝现象。     

不同产地瓠瓜品种ITS序列的遗传多样性分析

对国产29个瓠瓜也Lagenariasiceraria（Molina）Standl.页品种的ITS序列进行了扩增及测序,并结合引自GenBank的国产9个瓠瓜品种以及国外6个瓠瓜品种和3个同属种类的ITS序列,对它们的ITS序列长度和GC含量以及变异位点进行比较,在此基础上构建系统发育树并对47个样本间的遗传关系进行研究。结果显示：供试47个样本的ITS序列均由ITS1、5.8SrDNA及ITS2组成,各样本间的ITS序列长度、GC含量以及变异位点差异明显。国产38个瓠瓜品种的ITS序列（包括ITS1、5.8SrDNA及ITS2）长度为619-627bp、GC含量为58.00%-63.32%;国外9个样本的ITS序列长度为591-626bp,GC含量为54.17%-63.26%。序列比对结果显示：国产38个瓠瓜品种的ITS序列同源率为84.6%-100.0%,包含221个变异位点;其中,来源于山东的品种‘砧木2’（‘ZhenmuNo.2’）的ITS序列包含的变异位点最多,与其他品种间的同源率也最低。在系统发育树上,国产38个瓠瓜品种可分为3个分支,来源于山东的品种‘砧木2’和来源于河南的品种‘西瓜砧木1’（‘XiguazhenmuNo.1’）各自聚为第1和第2分支;其余36个品种聚为第3分支。而供试的47个样本则可分为2个分支和5个亚组,第1分支可分为2个亚组,包括国产品种‘砧木2’和产自日本的2个品种;第2分支包含的44个样本则进一步分为3个亚组,国产品种‘西瓜砧木1’和产自法国的品种‘白花瓠瓜’（‘White-floweredgourd’）各自聚为第1和第2亚组,其余的42个样本聚为第3亚组。研究结果表明：供试的不同产地瓠瓜品种间存在丰富的遗传变异和地理分化现象,其ITS序列差异与地理分布有一定关系。     

基于ITS 序列探讨沙棘属植物的系统发育关系

对分布于青海境内的中国沙棘、肋果沙棘和西藏沙棘的ITS区进行扩增和序列分析,并以胡颓子科胡颓子属沙枣为外类群,对胡颓子科沙棘属15种植物的ITS序列进行聚类分析, 探讨沙棘属各植物的亲缘关系.结果表明： 3种沙棘属植物的ITS区长度为600～605 bp,其中,ITS-1区为201～203 bp,5.8S为166～167 bp,ITS-2区为232～236 bp.核苷酸分析显示,3种沙棘属植物的ITS区存在丰富的变异位点.聚类分析表明,棱果沙棘种的2个亚种——棱果沙棘和理塘沙棘为2个不同种,江孜沙棘与柳叶沙棘之间的亲缘关系较近,而与中国沙棘亲缘关系较远;沙棘种下9个亚种间的聚类结果与形态学分类差异较大.
     

枇杷属内栽培种和部分野生种ITS序列分析

对不同栽培区的25种普通枇杷品种以及7种枇杷属野生种的ITS序列进行扩增并测序,采用邻接法和最大简约法进行系统发育树的构建并对枇杷属内不同种间的遗传关系进行了分析。结果表明:枇杷属植物ITS序列ITS1+5.8S rDNA+ITS2总长度为592 bp或594 bp,长度变化发生在ITS2。所有样本的ITS1和5.8S rDNA长度一样,都是223 bp和168 bp;而ITS2为201 bp或203 bp。5种枇杷属野生种的ITS序列长度为594 bp,包括栎叶枇杷、大渡河枇杷、南亚枇杷、南亚枇杷窄叶变种和大瑶山枇杷;其余2种枇杷属野生种(麻栗坡枇杷、小叶枇杷)和普通枇杷栽培种的ITS序列长度都为592 bp。所有样本ITS序列的GC含量为64.2%~64.5%,其中ITS1为64.1%~65.5%,ITS2为68.1%~72.6%。对所有样本的ITS序列比对产生44个可变位点,其中38个为简约信息位点,其中11个位于ITS1,5个位于5.8S rDNA,22个位于ITS2。最大的种间序列差异为7.7%,最小的种间差异发生在麻栗坡枇杷和小叶枇杷之间,仅为0.2%。普通枇杷种内的ITS序列差异很低,25种普通枇杷栽培种之间的序列差异为0~1.5%。所研究的枇杷属植物可分为3个分支。分支Ⅰ包括所有普通枇杷品种,分支Ⅱ包含5种野生枇杷种,包括栎叶枇杷、大渡河枇杷、南亚枇杷、南亚枇杷窄叶变种和大瑶山枇杷;分支Ⅲ由2个野生枇杷种(麻栗坡枇杷、小叶枇杷)组成。该研究结果表明ITS序列对枇杷种间鉴定和系统发育分析具有一定意义,但对普通枇杷栽培种间的鉴定作用不大。     

国产“水山姜”的分类学研究—来自核糖体DNA ITS区序列的证据

用直接测序法对国产黑果山姜Alpinia nigra(Gaertn.)Burtt以及“水山姜Alpinia aquatica (Koen.)Rose”。的核糖体DNA中的内转录间隔区（ITS）序列进行了测定,结果显示两者序列完全一致;ITS1长度为178bp,ITS2长度为232bp,5.8S编码区长度为164bp,GC含量为56.9%,形态学特征结合DNA分子证据,认为《中国植物志》记载的水山姜实为黑果山姜。     

Capping DNA with DNA

Twelve classes of deoxyribozymes that promote an ATP-dependent "self-capping" reaction were isolated by in vitro selection from a random-sequence pool of DNA. Each deoxyribozyme catalyzes the transfer of the AMP moiety of ATP to its 5'-terminal phosphate group, thereby forming a 5',5'-pyrophosphate linkage. An identical DNA adenylate structure is generated by the T4 DNA ligase during enzymatic DNA ligation. A 41-nucleotide class 1 deoxyribozyme requires Cu(2+) as a cofactor and adopts a structure that recognizes both the adenine and triphosphate moieties of ATP or dATP. The catalytic efficiency for this DNA, measured at 10(4) M(-1) x min(-1) using either ATP or dATP as substrate, is similar to other catalytic nucleic acids that use small substrates. Chemical probing and site-directed mutagenesis implicate the formation of guanine quartets as critical components of the active structure. The observation of ATP-dependent "self-charging" by DNA suggests that DNA could be made to perform the reactions typically associated with DNA cloning, but without the assistance of protein enzymes.     

Eukaryotic DNA polymerases in DNA replication and DNA repair

DNA polymerases carry out a large variety of synthetic transactions during DNA replication, DNA recombination and DNA repair. Substrates for DNA polymerases vary from single nucleotide gaps to kilobase size gaps and from relatively simple gapped structures to complex replication forks in which two strands need to be replicated simultaneously. Consequently, one would expect the cell to have developed a well-defined set of DNA polymerases with each one uniquely adapted for a specific pathway. And to some degree this turns out to be the case. However, in addition we seem to find a large degree of cross-functionality of DNA polymerases in these different pathways. DNA polymerase α is almost exclusively required for the initiation of DNA replication and the priming of Okazaki fragments during elongation. In most organisms no specific repair role beyond that of checkpoint control has been assigned to this enzyme. DNA polymerase δ functions as a dimer and, therefore, may be responsible for both leading and lagging strand DNA replication. In addition, this enzyme is required for mismatch repair and, together with DNA polymerase ζ, for mutagenesis. The function of DNA polymerase ɛ in DNA replication may be restricted to that of Okazaki fragment maturation. In contrast, either polymerase δ or ɛ suffices for the repair of UV-induced damage. The role of DNA polymerase β in base-excision repair is well established for mammalian systems, but in yeast, DNA polymerase δ appears to fullfill that function. Received: 20 April 1998 / Accepted: 8 May 1998     

DNA supercoiling by DNA gyrase

Using purified DNA gyrase to supercoil circular plasmid pBR322 DNA, we examined how the linking number attained at the steady state (‘static head’) varies with the concentrations of ATP and ADP, both in the absence and presence of spermidine. In the absence of spermidine at total adenine nucleotide concentrations between 0.35 and 1.4 mM, the static-head linking number was independent of the sum concentration of ATP and ADP, but depended strongly on the ratio of their concentrations. We established that the same linking number was attained independent of the direction from which the steady state was approached. The decrease in linking number at static head is more extensive when spermidine is present in the incubation, but remains a function of the [ATP]-to-[ADP] ratio. These results are discussed in terms of various kinetic schemes for DNA gyrase. We present one kinetic scheme that accounts for the experimental observations. According to this scheme our experimental results imply that there is significant slip in DNA gyrase when spermidine is absent. It is possible that spermidine acts through adjustment of the degree of coupling of DNA gyrase.     

DNA topoisomerases and DNA repair

DNA topoisomerases are enzymes that can modify, and may regulate, the topological state of DNA through concerted breaking and rejoining of the DNA strands. They have been believed to be directly involved in DNA excision repair, and perhaps to be required for the control of repair as well. The vicissitudes of this hypothesis provide a noteworthy example of the dangers of interpreting cellular phenomena without genetic information and vice versa.     

DNA knots and DNA supercoiling

Comment on: Witz G, et al. Proc Natl Acad Sci USA 2011; 108:3608-11.     

DNA supercoiling inhibits DNA knotting

Despite the fact that in living cells DNA molecules are long and highly crowded, they are rarely knotted. DNA knotting interferes with the normal functioning of the DNA and, therefore, molecular mechanisms evolved that maintain the knotting and catenation level below that which would be achieved if the DNA segments could pass randomly through each other. Biochemical experiments with torsionally relaxed DNA demonstrated earlier that type II DNA topoisomerases that permit inter- and intramolecular passages between segments of DNA molecules use the energy of ATP hydrolysis to select passages that lead to unknotting rather than to the formation of knots. Using numerical simulations, we identify here another mechanism by which topoisomerases can keep the knotting level low. We observe that DNA supercoiling, such as found in bacterial cells, creates a situation where intramolecular passages leading to knotting are opposed by the free-energy change connected to transitions from unknotted to knotted circular DNA molecules.     

DNA杂交与DNA指纹技术

Southern印迹杂交和DNA指纹技术在分子生物学研究以及疾病的诊断、亲缘关系鉴定、犯罪分子确认等过程中发挥了重要作用。回顾了2种技术的发明、发展历程和在生命科学研究中的作用,并探讨了可能的发展方向,从中可以从一个侧面了解分子生物学的发展历程和体会科学家的智慧在科学技术发展中所起的重要作用。     

Active DNA demethylation and DNA repair

DNA methylation on cytosine is an epigenetic modification and is essential for gene regulation and genome stability in vertebrates. Traditionally DNA methylation was considered as the most stable of all heritable epigenetic marks. However, it has become clear that DNA methylation is reversible by enzymatic “active” DNA demethylation, with examples in plant cells, animal development and immune cells. It emerges that “pruning” of methylated cytosines by active DNA demethylation is an important determinant for the DNA methylation signature of a cell. Work in plants and animals shows that demethylation occurs by base excision and nucleotide excision repair. Far from merely protecting genomic integrity from environmental insult, DNA repair is therefore at the heart of an epigenetic activation process.